7 September 2011 Reflection-geometry sub-terahertz-wave imaging for biological materials using an integrated photonic transceiver
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Abstract
A photonic transceiver module integrating a uni-traveling-carrier photodiode, a Schottky barrier diode, and a planar circulator circuit has been developed for sub-terahertz(THz)-wave reflection-geometry imaging. All the components are assembled in a compact rectangular-waveguide-output package for operation in the J-band (220 - 325 GHz), and continuous sub-THz waves are generated by the photomixing. The frequency dependence of the detection sensitivity of the transceiver module exhibits clear resonant behavior at around 270 GHz. The peak internal signal-to-background (S/B) ratio is measured to be as large as about 10. The characteristic of the fabricated transceiver is evaluated by measuring two-dimensional images of a test sample at frequencies from 240 to 310 GHz. Although the image resolution degrades with signal frequency deviation from the resonant condition due to the S/B ratio decrease, it is confirmed that a practical contrast can be obtained for a bandwidth of about 40 GHz even with an S/B ratio below one. Based on these results, the reflection-geometry in-vivo imaging of a human finger at 270 GHz is successfully demonstrated.
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Hiroshi Ito, Hiroshi Yamamoto, Yoshifumi Muramoto, Tadao Ishibashi, "Reflection-geometry sub-terahertz-wave imaging for biological materials using an integrated photonic transceiver", Proc. SPIE 8119, Terahertz Emitters, Receivers, and Applications II, 811902 (7 September 2011); doi: 10.1117/12.892526; https://doi.org/10.1117/12.892526
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